EP0971550B1 - Method and mobile radio network for handling packet data service - Google Patents

Description

The invention relates to a method and a mobile radio network for handling a packet data service according to the preamble of patent claim 1 or claim 21.

For connection-oriented communication services in a communication network, it is known to allow the connections to be controlled by an intelligent network (IN). For example, for mobile networks according to the GSM (Global System for Mobile Communication) standard, a CAMEL (Customized Applications for Mobile Network Enhanced Logic) platform is defined in accordance with GSM Recommendation 03.78 in order to enable the world-wide use of IN features as far as possible. The usual architecture of the intelligent network provides a service switching function (Service Switching Function) and a service control function (Service Control Function), which are connected to each other via a signaling link, see for example the WO 97/27713 , As an application here is a special protocol used, which consists for example for the mobile network from the CAP protocol (CAMEL Application Part).

In existing mobile networks - such as the GSM standard - novel data services - such as the GPRS (General Packet Radio Service) according to the GSM recommendation 03.60 - introduced. The data transmission takes place here in the mobile network not connection-oriented, but in the form of packet data. The advantage of packet-oriented transmission is that it makes better use of the given transmission resources in the mobile network. The network architecture for the packet data service provides that the communication terminal used by the mobile subscriber - the mobile station - is served at its respective location by a special serving node (Serving GPRS Support Node). Around To receive or send packet data requires access to a packet data network. For this purpose, one or more access network nodes (Gateway GPRS Support Nodes) are provided, each of which realize this access to the packet data network - eg the Internet - while supporting an associated packet data protocol - eg the Internet Protocol. The packet data transmission takes place via a tunnel which is connected between service network nodes and access network nodes. Support for packet data transmission according to the packet data service by the usual IN architecture is currently not possible.

It is therefore an object of the present invention to provide a method and a mobile radio network, by means of which a treatment of the packet data service for packet data transmission over an IN architecture is made possible.

This object is achieved according to the invention in terms of the method by the features of claim 1 and in terms of the mobile network by the features of claim 21. Further developments of the invention can be found in the dependent claims.

Starting from the handling of a packet data service in the mobile network by a service network node in connection with an access network node for transmitting packet data according to the invention an interworking of the packet data service with network functions of an intelligent network, of which a service switching function interconnected with the service network node and a service control function via an interface to the service network node with integrated service switching function is turned on. Interworking with the integration of the service switching function in the service network nodes allows the handling of the packet data service via IN functions to be achieved in the first place, which has the advantage of a similar service treatment to all other IN services. The newly created interface for the Interworking between service network nodes with integrated service switching function and service control function thereby supports uniform service handling, which is thus applicable both for packet-oriented communication and for connection-oriented communication. The integration of the service switching function of the intelligent network in the service network nodes also has the advantage that the subscriber-related data required for service handling - such as the location of the mobile station, the identification data, etc. - the service switching function directly from the service network node - and not "detours" - can be made available.

It has proven advantageous according to a development of the invention that the service network node with integrated service switching function uses several states according to a state model for handling the packet data service and evaluates state transitions between the states for interworking with the network functions of the intelligent network.

According to another advantageous embodiment of the invention, messages for carrying out operations for the packet data service are sent and received via the interface between the service switching function and the service control function.

As a favorable variant of the interworking according to the invention has been found to use certain events as trigger points for the packet data service to open a communication between the service switching function and service control function. In addition, events can also be used as event points for the packet data service, the occurrence of which is reported in each case by the service switching node integrated service switching function.

FIG 1

das Blockschaltbild eines Mobilfunknetzes zur Behandlung des Paketdatendienstes gemäß der Erfindung,

FIG 2

das Blockschaltbild eines Zustandsmodells für die Behandlung des Paketdatendienstes in dem Dienstenetzknoten mit integrierter Dienstevermittlungsfunktion, und

FIG 3

den Nachrichtenfluß zwischen den Netzeinrichtungen am Beispiel einer Vorausvergebührung mittels IN-Funktion bei Übertragung von Paketdaten gemäß dem Paketdatendienst.

The invention will be explained in more detail with reference to an embodiment shown in the drawing. Show in detail

FIG. 1

the block diagram of a mobile network for handling the packet data service according to the invention,

FIG. 2

the block diagram of a state model for the treatment of the packet data service in the service network node integrated service switching function, and

FIG. 3

the message flow between the network devices on the example of a pre-charging by means of IN function in transmission of packet data according to the packet data service.

The block diagram of FIG. 1 shows the network architecture of a mobile radio network GPRS-N for handling a packet data service GPRS (General Packet Radio Service). As is known, the communication terminal MT-the mobile station-of a mobile subscriber is wirelessly coupled via an air interface Um to the mobile radio network GPRS-N, ie to its base station system BSS with stationary base stations and base station controllers. To transmit packet data between the mobile station MT and a packet data network PDN, the mobile radio network GPRS-N has a service network node SGSN and an access network node GGSN. The access network node GGSN is connected via an interface Gi with the packet data network PDN, while the service network node SGSN is connected to the base station system BSS via an interface Gb. In addition to the base station system BSS a switching system with usually several mobile exchanges and subscriber databases in the mobile network GPRS-N is provided. In the present example, a mobile switching center MSC with associated subscriber database VLR via an interface Gs and a central subscriber database HLR via an interface Gr to the service network node SGSN turned on. The subscriber databases VLR, HLR realized as registers are known to contain the subscriber and service data of the mobile subscriber, depending on the location of his mobile station MT.

In order to be able to handle the packet data service as an IN service, the interworking of the packet data service with network functions of an intelligent network (IN) takes place such that a service switching function SSF interconnects with the service network node SGSN and a service control function SCF via a new interface Gnew with the service network node SGSN integrated service switching function SSF is turned on. Since the service network node SGSN has the necessary subscriber-related data, such as e.g. the current location, the identification data, etc., he is the optimal place for the merge of the functions of the packet data service and the IN functions in the mobile network GPRS-N. In the service network node SGSN there is a packet relay, which inter alia maps the interface Gb to the base station system BSS on the interface Gn to the access network node GGSN and vice versa and forwards the data packets in both directions. In addition, this packet relay controls mobility management - e.g. here for the packet data service GPRS - and is conceptually used to integrate the service switching function SSF in the service network node SGSN.

• persönlich zugeordnete IN-Dienste, die in die Teilnehmerdatenbasis eingetragen werden, oder
• fest zugeordnete IN-Dienste, oder
• vom Teilnehmer selbst aktivierte IN-Dienste, z.B. über ein Parameterprofil.

The following mechanisms are conceivable for triggering the IN services, including the packet data service:

• personally assigned IN services, which are entered in the subscriber database, or
• permanently assigned IN services, or
• subscriber-activated IN services, eg via a parameter profile.

Initially there is no connection in the network for the packet data service. To use the service, the mobile subscriber must log in to the network - as well as connection-oriented services. On this occasion, his identity and authority will be checked. In the second step, a packet data protocol must be activated. The network GPRS-N now establishes a tunnel between the service network node SGSN and the access network node GGSN to the packet data network PDN. As a result, packets can be exchanged between the subscriber and the packet data network. The entirety of the states of a mobile subscriber with respect to the packet data service GPRS is referred to below as "session".

2 shows in a block diagram the state model for handling the packet data service in the service network node SGSN with integrated service switching function SSF according to FIG. 1. This state model derives from the "session" of a mobile subscriber and comprises several states for the mobile station MT of the mobile subscriber for interworking with the network functions of the intelligent network can be evaluated. A special feature is the transition to a new service network node SGSN, if the subscriber leaves the coverage area of an old service network node SGSN. The following states are to be distinguished:

IDLE

In this state, the mobile station is not logged in to the mobile network. Successfully logging in will make the transition to an ATTA (Attached) state - see below. From the states ATTA and another state PDPA (Packet Data Protocol ACTIVE) - see also below - the state IDLE can be reached by offloading from the network.

ATTA

This state is reached when the mobile station successfully logs in. Enabling a packet data protocol will reach the PDPA state. The status IDLE is reached by offloading from the network. In the ATTA state, it is also possible to update the location on the basis of a routing area. The latter events do not lead to a state transition.

PDPA

This condition is reached when a packet data protocol has been successfully activated by the mobile station. By logging out of the network, the IDLE state is reached. In the PDPA state, it is also possible to update the location on the basis of a cell area or a routing area. The latter events do not lead to a state transition. Other events that do not cause a state transition are sending or receiving a packet, as well as exceeding a threshold for sent and / or received packets.

• [1] Attach: ein Teilnehmer bzw. seine Mobilstation meldet sich im GPRS-Mobilfunknetz an, was den Übergang vom Zustand IDLE zum Zustand ATTA nach sich zieht.
• [2] PDP_Activate: ein Teilnehmer bzw. seine Mobilstation aktiviert ein Paketdatenprotokoll, was den Übergang vom Zustand ATTA zum Zustand PDPA bewirkt.

These state transitions are used for interworking between the service network node (SGSN, see FIG. 1) with the integrated service switching function (SSF, see FIG. 1) and the service control function (SCF, see FIG. 1). To initiate communication, for example a control or monitoring relationship, between the service switching function and the service control function, trigger points (trigger detection points, TDP) are required. The following events are preferably used as trigger points:

• Attach: a subscriber or his mobile station logs on in the GPRS mobile network, which entails the transition from the state IDLE to state ATTA.
• [2] PDP_Activate: a subscriber or his mobile station activates a packet data protocol, causing the transition from the ATTA state to the PDP A state.

All trigger points are possible both in a request mode and in a notification mode.

• [2] PDP_ Activate: ein Teilnehmer aktiviert ein Paketdatenprotokoll.
• [3] RoutingArea_Update: ein Teilnehmer wechselt in eine neue Routing Area.
• [4] Cell_Update: ein Teilnehmer wechselt in eine neue Funkzelle.
• [5] Packet_Receive: ein Teilnehmer empfängt zumindest ein Datenpaket.
• [6] Packet_Send: ein Teilnehmer sendet zumindest ein Datenpaket.
• [7] Packet_Threshold: die eingehenden und/oder ausgehenden Datenpakete eines Teilnehmers überschreiten einen zuvor definierten Schwellwert.
• [8] Detach: ein Teilnehmer meldet sich im GPRS-Mobilfunknetz ab.
• [9] PDP_Deactivate: ein Teilnehmer deaktiviert ein Paketdatenprotokoll.

The following events are used as event points (EDPs) for the packet data service, defining the actions of the mobile subscriber or of his mobile station MT and, when they occur, each initiating a message from the service switching function (SSF):

• [2] PDP_ Activate: a subscriber activates a packet data protocol.
• [3] RoutingArea_Update: a subscriber changes to a new routing area.
• [4] Cell_Update: a participant changes to a new radio cell.
• [5] Packet_Receive: a subscriber receives at least one data packet.
• [6] Packet_Send: a subscriber sends at least one data packet.
• [7] Packet_Threshold: the incoming and / or outgoing data packets of a subscriber exceed a previously defined threshold value.
• [8] Detach: a subscriber logs off in the GPRS mobile network.
• [9] PDP_Deactivate: a participant deactivates a packet data protocol.

The event points are first "armored" by the service switching function (SSF), ie the service control function (SCF) causes them to report the occurrence of a specific event. All event points are armable in both the request and message modes.

Certain operations are performed via the new interface between service switching function (SSF) and service control function (SCF). Each operation distinguishes between an initiating entity and a responding entity. The operations can be performed as well as connection-oriented transmission of voice signals based on CCS7 signaling. However, any other signaling is possible, e.g. The exchange of messages can also take place on the basis of Internet Protocol (IP) etc.

The following messages are intended for interworking between GPRS packet service and Intelligent Network:

IDP (InitialDetectionPoint)

This message is used to open the control or monitoring relationship between service switching function (SSF) and service control function (SCF) with respect to a GPRS subscriber. The message is triggered by reaching a trigger point. Preferably, certain conditions must additionally be fulfilled for the IDP operation to be triggered. There are different possibilities for this:

The event in question - for example attach - occurs and it is fixed in the service network node (SGSN) that an SSF / SCF association is to be opened. For this purpose, suitable data - the trigger profiles - are stored in the database of the service network node (SGSN), from which the address of the service switching function (SSF), as well as data that address the service, can be taken.

The relevant event - eg attach - occurs and the subscriber profile requested by the HLR indicates that an SSF / SCF association is to be opened. For this purpose, suitable data (see above) within the participant profile deposited (eg service indication as defined in CAMEL).

The event in question - e.g. RoutingArea_Update - Occurs and from the subscriber context data queried by the old SGSN upon a transition to a new SGSN, it appears that an SSF / SCF association is to be opened. For this, appropriate data (see above) is stored within the subscriber context data (e.g., service indication as defined in CAMEL).

The relevant event - eg PDP_Activate - comes in and the parameters of the messages at the interface to the base station system (G _b interface) indicate that a particular IN service is to be activated. The required service parameters are taken from a profile stored in the SGSN (see 1.). In the corresponding messages of the existing GPRS standard (to log in or activate a packet data protocol) suitable parameters for service selection must be included. It is also possible to use existing parameters, such as the type of packet data protocol provided for transmitting the packet data, or the address of the desired access network node of the mobile radio network.

• Teilnehmerkennung (IMSI) zur Identifikation des Teilnehmers
• eine Kennung (PDPContextIdentifier) der jeweiligen Paketdatenübertragung
• Location (= Zell-Identifikation) des Teilnehmers
• Typ des Triggerpunktes
• Gewünschter Paketdatenprotokolltyp (PDP Type)
• Gewünschter Zugriffspunkt (GGSN-Adresse oder Name)
• Gewünschte Dienstequalität (QoS, Quality of Service)
• Identifikation des Dienstes (Service Key)

If one of the above conditions is met, the service switching function (SSF) initiates the IDP operation by sending a message. The message contains the following parameters, among others:

• Subscriber identification (IMSI) for identification of the subscriber
• an identifier (PDPContextIdentifier) of the respective packet data transmission
• Location (= cell identification) of the participant
• Type of trigger point
• Desired packet data protocol type (PDP Type)
• Desired access point (GGSN address or name)
• Desired quality of service (QoS, Quality of Service)
• Identification of the service (service key)

The PDPContextIdentifier date allows the service control function (SCF) to uniquely identify a packet "session" in the GPRS mobile network. This is necessary, for example, if several packet data transmissions and thus several SCF / SSF associations exist for one subscriber.

If it is a trigger point in the request mode, the service control function (SCF) is now stopped, about the permissibility of the desired action - e.g. Activation of a packet data protocol - to decide. For this one of the following operations "GRA" or "REJ" is used.

GRA (Grant)

• Zulässige Dienstequalität (Quality of Service).
• Identifikation eines Zugriffspunkts (= GGSN-Adresse oder Name).

This operation is used by the service control function SCF to instruct the service switching function SSF to allow a desired action - eg activation of the packet data protocol. The operation is initiated by sending a message. Parameters include

• Permissible quality of service.
• Identification of an access point (= GGSN address or name).

The service switching function SSF or the service network node SGSN now continues the processing by e.g. a packet data log is activated. In doing so, parameters of the grant operation are taken into account, i. the subscriber may only receive the quality of service specified by the service control function SCF, and access to the packet data network is via the access node GGSN defined by the service control function SCF.

REJ (Reject)

This operation is used by the service control function SCF to instruct the service switching function SSF not to allow a desired action. The operation is initiated by sending a message. Parameters are i.a.

- cause for the rejection (reject cause)

The service switching function SSF or the service network node SGSN continues processing by denying the desired action or deactivating the packet data protocol from the network. For this purpose, it is necessary to send an appropriate message at the interface to the MS as provided in the protocol (GPRS Mobility Management: Attach Reject, Routing Area Update Reject, GPRS Session Management: Activate PDP Context Reject, Deactivate PDP context request).
The cause of the rejection can be mapped to the corresponding parameters of the above-mentioned messages to the mobile station.

RRBE (RequestReportBSSMEvent)

• Typ des/ bzw. der zu überwachenden Ereignisses
• Falls das Ereignis "Packet_Threshold" armiert wird:
  • Höhe des Schwellwertes.
  • Typ des Schwellwertes (Anzahl Bytes, Anzahl Pakete).
  • Zeitintervall für die Überwachung des Schwellwertes.
  • Zählmethode (seit Beginn der Übertragung, bei jedem Überlauf zurücksetzen, Bei Erhalt der Zählanweisung auf Null setzen).
  • Richtung (eingehend, abgehend, beide Richtungen)
  • Geforderte Reaktion bei Überschreitung (Abbruch der Übertragung, Lediglich Meldung).

This operation is used by the service control function SCF to instruct the service switching function SSF to monitor a particular event and report the occurrence of the event (see below, ERB operation). The operation is initiated by sending a message. Parameters include

• Type of event (s) to be monitored
• If the event "Packet_Threshold" is armed:
  • Height of the threshold.
  • Type of threshold (number of bytes, number of packets).
  • Time interval for monitoring the threshold value.
  • Counting method (since the beginning of the transmission, reset at every overflow, set to zero when the counting instruction is received).
  • Direction (incoming, outgoing, both directions)
  • Required reaction if exceeded (abort of transmission, only message).

The service switching function SSF now reports on admission the named event by means of ERB (EventReportBSSM).

ERB (EventReportBSSM)

• Typ des Ereignisses.
• Falls das Ereignis "Packet_Threshold" gemeldet wird: Höhe des aktuellen Zählstandes.

This operation is used by the service switching function SSF to notify the occurrence of a previously armed event to the service control function SCF. The operation is initiated by sending a message. Parameters include

• Type of event.
• If the event "Packet_Threshold" is reported: Height of the current count.

The service control function SCF registers the event and, if necessary, sends further instructions.

CAA (CancelAssociation)

• Rückmelden des abschließenden Zustandes (ja/nein).

This operation serves to terminate an association with a service switching function SSF. The operation is necessary in connection with the transition to a new SGSN or a new service switching function SSF. It is possible to query the final state of the packet session from the service switching function SSF. Parameters are:

• Feedback of the final state (yes / no).

If necessary, the service switching function SSF responds with CAR (CancelAssociationResponse).

CAR (CancelAssociationResponse)

• Zustand: Paket-Zählerstände für armierte Schwellwerte

This operation serves to confirm the termination of an association to a service control function SCF and to report the final state to the service control function SCF. Parameters are:

• Condition: Package counter readings for armed thresholds

The service control function SCF registers the status and, if necessary, issues instructions to the service switching function SSF upon transfer to the new SGSN.

An example of the application of the interworking according to the invention between the packet data service GPRS and the IN functions for similar treatment of all services relates to a prepaid service of the packet data transmission. This fee prepayment is realized via the Intelligent Network IN. Subscribers using this service through appropriate card contracts may also be offered the new data services, i. E. In this case, packet transmissions must be charged via the IN service.

1. (1) : Die Mobilstation MT meldet sich beim GPRS-Mobilfunknetz an und sendet ihre Identifizierungsdaten - Attach, Security functions - über das Basisstationssystem zum Dienstenetzknoten SGSN. In der Folge wird die Mobilstation MT in bekannter Weise gemäß dem GSM-Standard über die Teilnehmerdatenbasis HLR im Netz authentifiziert, wobei entsprechende Daten über den Dienstenetzknoten SGSN und das Basisstationssystem mit der Mobilstation MT ausgetauscht werden.
2. (2): Die Teilnehmerdatenbasis HLR sendet auf eine Anforderungsnachricht - Update Location - des Dienstenetzknotens SGSN die Teilnehmerdaten - InsertSubscriberData - und empfängt im Anschluss daran eine Bestätigungsnachricht - Insert-SubscriberDataAcknowledge - vom Dienstenetzknoten SGSN, durch die das Eintreffen der angeforderten Teilnehmerdaten bestätigt wird. Die Teilnehmerdaten enthalten auch Triggerdaten - IN trigger data - aus denen hervorgeht, daß der Teilnehmer einen persönlichen IN-Dienst - im vorliegenden Beispiel den Prepaid-Service - in Anspruch nimmt.
   Die Teilnehmerdatenbasis HLR beantwortet die Anforderung von Daten durch Aussenden einer Bestätigungsnachricht - UpdateLocationAcknowledge - zum Dienstenetzknoten SGSN. Der Einbuchungsvorgang wird durch Senden einer Nachricht - Attach Accept - vom Dienstenetzknoten SGSN zur Mobilstation MT und durch Rücksenden einer anderen Nachricht - Attach Complete - von der Mobilstation MT zum Dienstenetzknoten SGSN ausgeführt.
3. (3) : Der Teilnehmer versucht über seine Mobilstation MT mittels einer Nachricht - ActivatePDPContextRequest - ein Paketdatenprotokoll zu aktivieren. Wegen der Zuordnung eines IN-Dienstes in der Teilnehmerdatenbasis HLR führt dies dazu, daß ein IN-Dialog aufgenommen wird. Dabei sendet die Dienstevermittlungsfunktion SSF die Nachricht IDP (Initial Detection Point) an die Dienstesteuerungsfunktion SCF, in der u.a. die Teilnehmer-Identität IMSI, der gewünschte IN-Dienst, sowie die Daten PDP-Type, QoS zum gewünschten Paketdatenprotokoll übertragen werden.
   Für den Fall, dass eine Assoziation zwischen Dienstesteuerungsfunktion SCF und Dienstevermittlungsfunktion SSF bestanden hat und ein Umschalten dieser Assoziation von einem alten Dienstenetzknoten zu einem neuen Dienstenetzknoten SGSN erfolgt ist - erkennbar an der Nachricht IDP - beendet die Dienstesteuerungsfunktion SCF nun die bisherige Assoziation zum alten Dienstenetzknoten durch Auslösen einer Nachricht CAA (CancelAssociation). Der alte Dienstenetzknoten bestätigt die Beendigung der Assoziation durch Auslösen bzw. Senden einer Nachricht CAR (Cancel AssociationResponse), wobei sämtliche Zustandsdaten der Assoziation mitgesendet werden.
4. (4) : Die Dienstesteuerungsfunktion SCF prüft, ob der Teilnehmer die Berechtigung hat, das Paketdatenprotokoll mit der verlangten Dienstequalität QoS zu aktivieren und ob das Konto des Teilnehmers genügend Deckung aufweist. Ist dies der Fall, so sendet die Dienstesteuerungsfunktion SCF die Nachricht GRA zur Dienstevermittlungsfunktion SSF.
5. (5) : Die Dienstesteuerungsfunktion SCF setzt einen ersten Schwellwert für Datenpakete, indem sie die Nachricht RRBE (RequestReportBSSMEvent) zur Dienstevermittlungsfunktion SSF sendet, in der u.a. der Ereignispunkt Packet_Threshold und der Schwellwert Threshold für die eingehenden/abgehenden Datenpakete definiert sind.
6. (6) : Die Aktivierung des Paketdatenprotokolls beginnt, indem die Nachrichten CreatePDPContextRequest, CreatePDPContextResponse zwischen dem Dienstenetzknoten SGSN und dem Zugangsnetzknoten GGSN übertragen werden. Eine Bestätigung an die Mobilstation MT folgt in der Nachricht ActivatePDPContextAccept, die vom Dienstenetzknoten SGSN initiiert und über das Basisstationssystem weitergeleitet wird. Die Paketübertragungen in Richtung von der Mobilstation MT zum Dienstenetzknoten SGSN und vom Dienstenetzknoten SGSN zum Zugangsnetzknoten GGSN setzen ein, beginnend mit einem Paket 1 bis zu einem Paket n. Die eintreffenden Pakete werden dabei im Dienstenetzknoten SGSN zwischengespeichert.
7. (7): Es sei angenommen, daß nach dem übermittelten Paket n der Schwellwert erreicht ist. Die Dienstevermittlungsfunktion SSF unterbricht daher die Weiterleitung der Pakete an den Zugangsnetzknoten GGSN und meldet das Ereignis mittels der Nachricht ERB (EventReportBSSM) an die Dienstesteuerungsfunktion SCF. Die Nachricht ERB weist u.a. den Ereignispunkt Packet_Threshold und einen Zählerstand counter=n als Parameter auf.
8. (8) : Die Dienstesteuerungsfunktion SCF führt daraufhin eine Zwischenvergebührung für die bisher übertragenen Pakete durch. Die Berechnung der Gebühren erfolgt auf Basis des gemeldeten Volumens, wobei ein Tarifmodell angewendet wird, das den Preis pro Volumeneinheit (z.B. Kilobyte) unter Berücksichtigung weiterer Kriterien, wie z.B. Wochentag und Uhrzeit, sowie die Entfernung zwischen der Mobilstation MT und dem Zugangsnetzknoten GGSN, bestimmt. Sofern das Teilnehmerkonto weiterhin genügend Deckung aufweist, wird von der Dienstevermittlungsfunktion SSF ein neuer Schwellwert Threshold gesetzt und zusammen mit dem Ereignispunkt Packet_Threshold in der Nachricht RRBE (RequestReportBSSM Event) an die Dienstesteuerungsfunktion SCF gesendet. Die Paketübertragung kann durch den Dienstenetzknoten SGSN fortgesetzt werden, indem weitere Pakete n+ zum Zugangsnetzknoten GGSN gesendet werden. Falls keine Deckung des Kontos mehr vorhanden ist, sendet die Dienstesteuerungsfunktion SCF die Nachricht REJ (Reject). Die Dienstevermittlungsfunktion SSF bewirkt dann die Deaktivierung des Paketdatenprotokolls und signalisiert dies an die Mobilstation MT. Weitere Pakete werden in diesem Fall vom Dienstenetzknoten SGSN verworfen und nicht weitergeleitet.

3 shows the exemplary message flow between mobile station MT, service network node SGSN with integrated service switching function SSF, service control function SCF, subscriber database HLR and access network node GGSN on the basis of successive steps (1) to (8), which are explained below.

1. (1): The mobile station MT logs on to the GPRS mobile network and sends its identification data - attach, security functions - via the base station system to the service network node SGSN. As a result, the mobile station MT is authenticated in a known manner according to the GSM standard on the subscriber database HLR in the network, with corresponding data via the service network node SGSN and the base station system with the mobile station MT are exchanged.
2. (2): The subscriber database HLR sends the subscriber data - InsertSubscriberData to a request message - Update Location - of the service network node SGSN and subsequently receives an acknowledgment message - Insert-SubscriberDataAcknowledge - from the service network node SGSN, by which the arrival of the requested subscriber data is confirmed. The subscriber data also contain trigger data - IN trigger data - indicating that the subscriber is using a personal IN service - in this example the prepaid service.
   The subscriber database HLR answers the request for data by sending an acknowledgment message - UpdateLocationAcknowledge - to the service network node SGSN. The log-in procedure is performed by sending a message - Attach Accept - from the service network node SGSN to the mobile station MT and by sending another message - Attach Complete - from the mobile station MT to the service network node SGSN.
3. (3): The subscriber attempts to activate a packet data protocol via his mobile station MT by means of a message - ActivatePDPContextRequest. Because of the assignment of an IN service in the subscriber database HLR, this leads to an IN dialog being recorded. In this case, the service switching function SSF sends the message IDP (Initial Detection Point) to the service control function SCF, in which inter alia the subscriber identity IMSI, the desired IN service, and the data PDP-type, QoS are transmitted to the desired packet data protocol.
   In the event that an association between service control function SCF and service switching function SSF has existed and a switching of this association from an old one Serving network node is done to a new service network node SGSN - recognizable by the message IDP - the service control function SCF now ends the previous association to the old service network node by triggering a message CAA (CancelAssociation). The old service network node acknowledges the termination of the association by triggering a message CAR (Cancel AssociationResponse), with all association status data being sent along.
4. (4): The service control function SCF checks whether the subscriber has the authorization to activate the packet data protocol with the required quality of service QoS and whether the subscriber's account has sufficient coverage. If this is the case, the service control function SCF sends the message GRA to the service switching function SSF.
5. (5): The service control function SCF sets a first threshold for data packets by sending the message RRBE (RequestReportBSSMEvent) to the service switching function SSF, in which among other things the event point Packet_Threshold and the threshold value Threshold for the incoming / outgoing data packets are defined.
6. (6): Activation of the packet data protocol begins by transmitting the messages Create PDP ContextRequest, CreatePDPContextResponse between the service network node SGSN and the access network node GGSN. An acknowledgment to the mobile station MT follows in the ActivatePDPContextAccept message initiated by the service network node SGSN and forwarded via the base station system. The packet transmissions in the direction from the mobile station MT to the service network node SGSN and from the service network node SGSN to the access network node GGSN commence, starting with a packet 1 up to a packet n. The incoming packets are thereby buffered in the service network node SGSN.
7. (7): It is assumed that after the transmitted packet n the threshold is reached. The service switching function SSF therefore interrupts the forwarding of the packets to the access network node GGSN and reports the event to the service control function SCF by means of the message ERB (EventReportBSSM). The message ERB has, inter alia, the event point Packet_Threshold and a count counter = n as a parameter.
8. (8): The service control function SCF then performs intermediate charging for the previously transmitted packets. The calculation of the fees is based on the reported volume, using a tariff model that determines the price per unit volume (eg kilobytes) taking into account further criteria, such as day of the week and time, and the distance between the mobile station MT and the access network node GGSN , If the subscriber account still has sufficient coverage, the service switching function SSF sets a new threshold value Threshold and sends it together with the event point Packet_Threshold in the message RRBE (RequestReportBSSM Event) to the service control function SCF. The packet transmission may be continued by the service network node SGSN by sending further packets n + to the access network node GGSN. If the account is no longer covered, the service control function SCF sends the message REJ (Reject). The service switching function SSF then causes the deactivation of the packet data protocol and signals this to the mobile station MT. Further packets are discarded in this case by the service network node SGSN and not forwarded.

Claims (23)

1. Method for handling a packet data service in a mobile radio network by a serving GPRS support node (SGSN) which is connected to a gateway GPRS support node (GGSN) for connection to a packet data network (PDN) for transmission of packet data from or to a mobile terminal (MT) of a mobile subscriber of the mobile radio network
   characterised by
   interworking between the packet data service and network functions of an Intelligent Network, of which a service switching function (SSF) is connected to the serving GPRS support node (SGSN) and a service control function (SCF) is connected via an interface (Gnew) to the serving GPRS support nodes with integrated service switching function (SGSN/SSF).
2. Method according to claim 1,
   characterised in that
   a number of states (IDLE, ATTA, PDPA) are used in accordance with a status model by the serving GPRS support nodes with integrated service switching function (SGSN/SSF) for handling the packet data service and status transitions between the states (IDLE, ATTA, PDPA) are evaluated for the interworking with the network functions of the intelligent network.
3. Method according to claim 1 or 2,
   characterised in that
   specific events (PDP_Activate, Attach) are used as trigger points for the packet data service to open a communication between service switching function (SSF) and service control function (SCF).
4. Method according to claim 3,
   characterised in that
   the event (Attach) consists of booking the mobile terminal (MT) into the mobile radio network.
5. Method according to claim 3,
   characterised in that
   the event (PDP_Activate) consists of the activation of a packet data protocol by the mobile terminal (MT).
6. Method according to claim 1 or 2,
   characterised in that
   existing parameters in the packet data network (PDN) are used as trigger points for the packet data service to open a communication between service switching function (SSF) and service control function (SCF).
7. Method according to claim 6,
   characterised in that
   the type of a packet data protocol provided for transmission of the packet data or the address of the gateway network node of the mobile radio network is used as a parameter.
8. Method according to one of the previous claims,
   characterised in that
   specific events (PDP_Activate, Detach, PDP_Deactivate, Packet_Threshold) are used as event detection points for the packet data service, of which the arrival is reported in each case by the service switching function integrated into the serving GPRS support node (SGSN/SSF).
9. Method according to one of the previous claims,
   characterised in that
   messages (IDP, GRA, RRBE, ERB, CAA, CAR) are sent and received over the interface (Gnew) for executing operations for interworking between service switching function (SSF) and service control function (SCF).
10. Method according to claim 9,
    characterised in that
    a message (IDP) to open an association between service switching function (SSF) and service control function (SCF) is triggered when a trigger point is reached.
11. Method according to claim 10,
    characterised in that
    subscriber data stored for the relevant mobile subscriber in the mobile radio network is used to determine whether the message (IDP) for opening an association is triggered.
12. Method according to claim 10,
    characterised in that
    subscriber context data which is requested on passing from one serving GPRS support node to another serving GPRS support node is used to determine whether the message (IDP) for opening an association is triggered.
13. Method according to claim 9,
    characterised in that
    a message (GRA) for requesting the service switching function to grant a particular action is triggered by the service control function (SCF).
14. Method according to claim 9,
    characterised in that
    a message (REJ) for requesting the service switching function to reject a particular action is triggered by the service control function (SCF), containing at least the cause of the rejection as a parameter.
15. Method according to claim 9,
    characterised in that
    a message (RRBE) for requesting the service switching function to monitor a particular event and report the arrival of the event is triggered by the service control function (SCF).
16. Method according to claim 15,
    characterised in that
    a message (ERB) for reporting the arrival of the event to the service control function (SCF) is triggered by the service switching function (SSF).
17. Method according to claim 9,
    characterised in that
    a message (CAA) for cancelling the association between service control function (SCF) and service switching function (SSF) is triggered by the service control function (SCF) to the service switching function (SSF).
18. Method according to claim 17,
    characterised in that
    a message (CAR) for confirming the cancellation of the association is triggered by the service switching function (SSF) to the service control function (SCF).
19. Method according to claims 9 to 18,
    characterised in that
    a number of parameters (e.g. IMS1, PDP type, QoS) are transferred in the messages (e.g. IDP) for the operation to be executed.
20. Method according to one of the previous claims,
    characterised in that
    the interworking between the packet data service and the service switching function integrated into the serving GPRS support node (SGSN/SSF) as well as the service control function (SCF) are applied to preliminary charging for packet data transmission.
21. Mobile radio network for handling a packet data service by a serving GPRS support node (SGSN) which is connected to a gateway GPRS support node (GGSN) for connection to a packet data network (PDN) for transmission of packet data from or to a mobile terminal (MT) of a mobile subscriber of the mobile radio network,
    characterised in that,
    for interworking between the packet data network and network functions of an Intelligent Network, the serving GPRS support node (SGSN) is provided with a service switching function, and a service control function (SCF) is connected via an interface (Gnew) to the serving GPRS support nodes with integrated service switching function (SGSN/SSF).
22. Mobile radio network according to claim 21,
    characterised in that
    the interface (Gnew) is provided for transmission of messages (IDP, GRA, RRBE, ERB, CAA, CAR) for executing operations according to the packet data service.
23. Mobile radio network according to claim 22,
    characterised in that
    the messages (e.g. IDP) have a number of parameters (e.g. IMS1, PDP type, QoS) for the operation to be executed.

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